Electrolytic cell with independent oxygen and hydrogen outputs

Abstract

The utility model discloses an electrolytic cell with oxygen and hydrogen independent output, including electrolytic shell, the middle part of electrolytic shell top is equipped with electrolytic cell, the middle part of electrolytic cell inner wall bottom is fixedly installed with diaphragm, both sides of electrolytic cell inner wall bottom are slidably connected with two electrolytic components, and the top of electrolytic shell is equipped with sealing cover, and the four corners of sealing cover bottom are fixedly installed with the clamping mechanism, and two electrolytic components all include motor base and reversible motor, the utility model discloses an electrolytic cell with oxygen and hydrogen independent output, through setting electrolytic component, and the limiting plate is pushed from one side to push the shell, and the size of positive and negative electrolytic chamber is adjusted, and then, the user adjusts the distance between electrode sheet and limiting plate relative to screw rod rotation installation shell, and electrode sheet and electrolyte are in overall contact, improve electrolyte electrolysis efficiency, satisfy the demand of people to hydrogen preparation.

Description

Technical Field

[0001] This utility model relates to the field of electrolytic cell technology, specifically to an electrolytic cell with independent output of oxygen and hydrogen. Background Technology

[0002] An electrolyzer, also known as a hydrogen electrolyzer, is a device used for the production of hydrogen and oxygen. It converts electrical energy into chemical energy through the electrolysis of water, causing water molecules to decompose into hydrogen and oxygen. This process mainly takes place in a specially designed electrolyzer, involving electron transfer between the anode and cathode. Hydrogen electrolyzers are widely used in hydrogen production, energy storage, and fuel cells. By using renewable energy sources such as solar, wind, or hydropower as a power source, hydrogen electrolyzers provide a more sustainable and environmentally friendly method for producing hydrogen.

[0003] However, traditional electrolytic cells have the following disadvantages:

[0004] Traditional electrolyzers have a fixed contact area with the electrolyte, resulting in low electrolyte electrolysis efficiency, which cannot meet people's needs for hydrogen production. Utility Model Content

[0005] The purpose of this invention is to provide an electrolyzer with independent output of oxygen and hydrogen, in order to solve the problem mentioned in the background art that the contact area between the traditional electrolyzer and the electrolyte is fixed, resulting in low electrolyte electrolysis efficiency and failing to meet people's demand for hydrogen production.

[0006] To achieve the above objectives, this utility model provides the following technical solution: an electrolytic cell with independent output of oxygen and hydrogen, comprising an electrolytic shell, an electrolytic cell formed at the center of the top of the electrolytic shell, a diaphragm fixedly installed at the center of the bottom of the inner wall of the electrolytic cell, two electrolytic components slidably connected to both sides of the bottom of the inner wall of the electrolytic cell, a sealing cover provided at the top of the electrolytic shell, and locking mechanisms fixedly installed at the four corners of the bottom of the sealing cover, each of the two electrolytic components comprising a motor base and a forward and reverse motor, the top of the motor base being fixedly connected to the bottom of the forward and reverse motor, a lead screw provided at the top of the forward and reverse motor, a push shell threadedly connected to one end of the lead screw, a limiting plate rotatably connected to the electrolytic cell on one side of the push shell, and an electrode plate provided on one side of the limiting plate.

[0007] Preferably, a screw is rotatably connected to the top of one side of the limiting plate, and a mounting shell is threaded to one end of the screw. One end of the mounting shell is fixedly connected to one side of the electrode plate. When the user rotates the mounting shell, the threads on the surface of the mounting shell match the threads on the inner wall of the screw, so the mounting shell rotates and translates relative to the screw. The mounting shell pushes the electrode plate from one side to adjust the distance between the electrode plate and the limiting plate.

[0008] Preferably, a rotating shaft is fixedly installed at the output end of the reversible motor. A drive pulley is fixedly installed on the surface of the rotating shaft, and a driven pulley is fixedly installed on the surface of the lead screw. A connecting belt connects the drive pulley and the driven pulley. When the reversible motor is powered on, it starts and drives the rotating shaft to rotate. The rotating shaft drives the drive pulley to rotate, and the drive pulley drives the driven pulley to rotate through the connecting belt. The driven pulley drives the lead screw to rotate. The thread on the surface of the lead screw matches the thread on the inner wall of the push housing, so the push housing rotates and translates relative to the lead screw. The push housing pushes the limiting plate from one side to adjust the size of the independent hydrogen or oxygen electrolysis chamber.

[0009] Preferably, one end of the motor base is fixedly connected to the electrolysis shell, and the electrolysis assembly is mounted on the electrolysis shell through the motor base.

[0010] Preferably, both ends of the electrolytic shell are fixedly connected to exhaust pipes extending to the outside. The hydrogen and oxygen generated by ionization inside the electrolytic shell are discharged to the outside through the exhaust pipes.

[0011] Preferably, each of the four locking mechanisms includes a locking block and two anti-sliding blocks. The two sides of the bottom end of the locking block are rotatably connected to the top ends of the two anti-sliding blocks respectively. A connecting spring is fixedly installed between the two anti-sliding blocks. When the user presses the anti-sliding blocks, the two anti-sliding blocks deflect at an angle relative to the locking block, and the two anti-sliding blocks are squeezed from both sides of the connecting spring, so that the anti-sliding blocks are locked in the slot.

[0012] Preferably, the top of the electrolytic shell has four slots, the four blocks are respectively set to correspond to the four slots, the opposite sides of the eight anti-sliding blocks are respectively in contact with the two sides of the inner wall of the four slots, and the sealing cover is fastened to the electrolytic shell by a locking mechanism.

[0013] Compared with the prior art, the beneficial effects of this utility model are: by setting up an electrolysis component, the push shell pushes the limiting plate from one side to adjust the size of the positive and negative electrode electrolysis chambers. Then, the user rotates the mounting shell relative to the screw to adjust the distance between the electrode plate and the limiting plate. The electrode plate is in full contact with the electrolyte, improving the electrolysis efficiency of the electrolyte and meeting people's needs for hydrogen production. Attached Figure Description

[0014] Figure 1 This is a perspective view of the present utility model;

[0015] Figure 2 This is a cross-sectional view of the present invention;

[0016] Figure 3 This is a side view of the electrolysis assembly of this utility model;

[0017] Figure 4This is a diagram showing the connection between the locking mechanism and the sealing cap of this utility model.

[0018] In the diagram: 1. Electrolysis shell; 2. Electrolysis assembly; 201. Motor base; 202. Forward and reverse motor; 203. Rotating shaft; 204. Drive pulley; 205. Driven pulley; 206. Connecting belt; 207. Lead screw; 208. Push shell; 209. Limiting plate; 210. Screw; 211. Mounting shell; 212. Electrode plate; 3. Exhaust pipe; 4. Sealing cover; 5. Clamping mechanism; 51. Clamping block; 52. Anti-slip block; 53. Connecting spring; 6. Slot; 7. Electrolysis cell; 8. Diaphragm. Detailed Implementation

[0019] The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present invention.

[0020] Please see Figure 1-4 This utility model provides an electrolytic cell with independent output of oxygen and hydrogen, including an electrolytic shell 1, an electrolytic cell 7 formed at the middle of the top of the electrolytic shell 1, a diaphragm 8 fixedly installed at the middle of the bottom of the inner wall of the electrolytic cell 7, two electrolytic components 2 slidably connected to both sides of the bottom of the inner wall of the electrolytic cell 7, a sealing cover 4 provided at the top of the electrolytic shell 1, and a locking mechanism 5 fixedly installed at the four corners of the bottom of the sealing cover 4. Each electrolytic component 2 includes a motor base 201 and a forward and reverse motor 202. The top of the motor base 201 is fixedly connected to the bottom of the forward and reverse motor 202. The top of the forward and reverse motor 202 is provided with a lead screw 207. One end of the lead screw 207 is threadedly connected to a push shell 208. A limiting plate 209 slidably connected to the electrolytic cell 7 is rotatably connected to one side of the push shell 208. An electrode plate 212 is provided on one side of the limiting plate 209.

[0021] A screw 210 is rotatably connected to the top of one side of the limiting plate 209. One end of the screw 210 is threadedly connected to a mounting shell 211. One end of the mounting shell 211 is fixedly connected to one side of the electrode plate 212. When the user rotates the mounting shell 211, the threads on the surface of the mounting shell 211 match the threads on the inner wall of the screw 210. Therefore, the mounting shell 211 rotates and translates relative to the screw 210. The mounting shell 211 pushes the electrode plate 212 from one side to adjust the distance between the electrode plate 212 and the limiting plate 209.

[0022] A rotating shaft 203 is fixedly installed at the output end of the reversible motor 202. A drive pulley 204 is fixedly installed on the surface of the rotating shaft 203, and a driven pulley 205 is fixedly installed on the surface of the lead screw 207. A connecting belt 206 is connected between the drive pulley 204 and the driven pulley 205. When the reversible motor 202 is powered on, it starts and drives the rotating shaft 203 to rotate. The rotating shaft 203 drives the drive pulley 204 to rotate. The drive pulley 204 drives the driven pulley 205 to rotate through the connecting belt 206. The driven pulley 205 drives the lead screw 207 to rotate. The thread on the surface of the lead screw 207 matches the thread on the inner wall of the push housing 208. Therefore, the push housing 208 rotates and translates relative to the lead screw 207. The push housing 208 pushes the limiting plate 209 from one side to adjust the size of the independent hydrogen or oxygen electrolysis chamber.

[0023] One end of the motor base 201 is fixedly connected to the electrolysis shell 1, and the electrolysis assembly 2 is mounted on the electrolysis shell 1 through the motor base 201.

[0024] Both ends of the electrolytic shell 1 are fixedly connected to exhaust pipes 3 extending to the outside. The hydrogen and oxygen generated by ionization inside the electrolytic shell 1 are discharged to the outside through the exhaust pipes 3.

[0025] Each of the four locking mechanisms 5 includes a locking block 51 and two anti-sliding blocks 52. The two sides of the bottom end of the locking block 51 are rotatably connected to the top ends of the two anti-sliding blocks 52 respectively. A connecting spring 53 is fixedly installed between the two anti-sliding blocks 52. When the user presses the anti-sliding blocks 52, the two anti-sliding blocks 52 deflect at an angle relative to the locking block 51, and the two anti-sliding blocks 52 are squeezed from both sides of the connecting spring 53, so that the anti-sliding blocks 52 are locked in the locking groove 6.

[0026] The top of the electrolytic shell 1 has four slots 6, and four locking blocks 51 are respectively set to correspond to the four slots 6. The opposite sides of the eight anti-sliding blocks 52 are respectively in contact with the two sides of the inner wall of the four slots 6. The sealing cover 4 is fastened to the electrolytic shell 1 by the locking mechanism 5.

[0027] In this embodiment, when in use: the forward and reverse motor 202 starts after being powered on, driving the rotating shaft 203 to rotate. The rotating shaft 203 drives the driving pulley 204 to rotate, which in turn drives the driven pulley 205 to rotate via the connecting belt 206. The driven pulley 205 drives the lead screw 207 to rotate. The threads on the surface of the lead screw 207 match the threads on the inner wall of the push housing 208, so the push housing 208 rotates and translates relative to the lead screw 207. The push housing 208 pushes the limiting plate 209 from one side, thus controlling the hydrogen gas. Alternatively, the size of the independent oxygen electrolysis chamber can be adjusted. The user rotates the mounting shell 211, and the threads on the surface of the mounting shell 211 match the threads on the inner wall of the screw 210. Therefore, the mounting shell 211 rotates and translates relative to the screw 210. The mounting shell 211 pushes the electrode plate 212 from one side, adjusting the distance between the electrode plate 212 and the limiting plate 209. The electrolyte is placed in the electrolysis shell 1, and the diaphragm 8 separates the electrolyte. The two electrode plates 212 are the positive electrode plate and the negative electrode plate, respectively, so that the electrolyte is electrolyzed to produce hydrogen or oxygen.

[0028] Although the present invention has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present invention should be included within the protection scope of the present invention.

Claims

1. An electrolytic cell with independent output of oxygen and hydrogen, comprising an electrolytic shell (1), characterized in that: An electrolytic cell (7) is provided at the middle of the top of the electrolytic shell (1). A diaphragm (8) is fixedly installed at the middle of the bottom of the inner wall of the electrolytic cell (7). Two electrolytic components (2) are slidably connected to both sides of the bottom of the inner wall of the electrolytic cell (7). A sealing cover (4) is provided at the top of the electrolytic shell (1). A locking mechanism (5) is fixedly installed at the four corners of the bottom of the sealing cover (4). Both electrolytic components (2) include a motor base (201) and a front and rear... The top end of the motor base (201) is fixedly connected to the bottom end of the reversible motor (202). The top end of the reversible motor (202) is provided with a lead screw (207). One end of the lead screw (207) is threadedly connected to a push shell (208). One side of the push shell (208) is rotatably connected to a limiting plate (209) that is slidably connected to the electrolytic cell (7). One side of the limiting plate (209) is provided with an electrode plate (212).

2. The electrolytic cell with independent output of oxygen and hydrogen according to claim 1, characterized in that: A screw (210) is rotatably connected to the top of one side of the limiting plate (209), and a mounting shell (211) is threaded to one end of the screw (210). One end of the mounting shell (211) is fixedly connected to one side of the electrode plate (212).

3. An electrolytic cell with independent output of oxygen and hydrogen according to claim 1, characterized in that: The output end of the reversible motor (202) is fixedly mounted with a rotating shaft (203), a drive pulley (204) is fixedly mounted on the surface of the rotating shaft (203), a driven pulley (205) is fixedly mounted on the surface of the lead screw (207), and a connecting belt (206) is connected between the drive pulley (204) and the driven pulley (205).

4. An electrolytic cell with independent output of oxygen and hydrogen according to claim 1, characterized in that: One end of the motor base (201) is fixedly connected to the electrolytic shell (1).

5. An electrolytic cell with independent output of oxygen and hydrogen according to claim 1, characterized in that: Both ends of the electrolytic shell (1) are fixedly connected to exhaust pipes (3) extending to the outside.

6. An electrolytic cell with independent output of oxygen and hydrogen according to claim 1, characterized in that: Each of the four locking mechanisms (5) includes a locking block (51) and two anti-slip blocks (52). The two sides of the bottom end of the locking block (51) are rotatably connected to the top ends of the two anti-slip blocks (52), and a connecting spring (53) is fixedly installed between the two anti-slip blocks (52).

7. An electrolytic cell with independent output of oxygen and hydrogen according to claim 6, characterized in that: The top of the electrolytic shell (1) has four slots (6), and the four card blocks (51) are respectively set in the four slots (6). The opposite sides of the eight anti-slip blocks (52) are respectively in contact with the two sides of the inner wall of the four slots (6).

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